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DEVELOPMENT AND TESTING OF A CROSS FLOW TURBINE
A Tamil ChandranResearch Engineer
Fluid Control Research Institute, Palakkad, India
G AnilHead, SHP Division
Energy Management Centre, Thiruvanandapuram, India
Jacob ChandapillaiHead, Centre for Water Management
Fluid Control Research Institute, Palakkad, India
SYNOPSISIn many hilly areas where there is no electric grid, good potential is available for the development
of micro hydro power. In such cases, small scale hydropower can be used as decentralised source of powerwhich can be used to meet local requirement. Small scale Micro hydropower stations combine the
advantages of hydropower with those of decentralised power generation, without the disadvantages of large
scale installations. Micro hydro power becomes quite cost effective if it is locally implemented and
maintained. Cross-flow turbines are considered as a favourable choice to meet the prevailing field
conditions in general.
In the above scenario, a cross flow micro turbine is developed for matching the head range of 5m
to 60m with the flow rate of 10 lps to 70 lps. The turbine has been developed such a way that it can be
fabricated, commissioned and maintained easily by making the effective use of locally available resources
like fabrication facility, semi skilled labour and available material. This way, the locally available untapped
hydraulic resource can be utilized for generating energy in a cost effective manner.
Performance of the developed turbine was studied in detail using a dedicated test set-up. Therequired head at the upstream of turbine and flow through the turbine was generated by pumping of waterfrom a sump. A calibrated Electro magnetic flow meter is fixed at the upstream side for the flow rate
measurement. Pressure at the upstream of the turbine was measured using a high precision pressure gauge.
Flow passed through the turbine was allowed to discharge freely into a sump. During the testing a control
valve and by-pass arrangement available at upstream side of the turbine was used for achieving the desired
flow and head. For output measurement, the turbine was coupled to an eddy current dynamometer through a
Torque transducer. Experiments were repeated at different heads and different guide vane opening, and the
performance is presented in the form of hill diagram.
The successful development of the cross-flow turbine is expected to benefit several households
who were deprived of electricity. The turbine developed is presently available to public for installation.
1. INTRODUCTIONHydropower is a very clean source of energy. It does not consume but only uses the water, after
use it is available for other purposes. The conversion of the potential energy of water into mechanical
energy is a technology with a high efficiency. The use of hydropower can make significant savings on
exhaustible energy sources.
In many of the hilly areas there are no electric grids, good potential is available for the development of
micro hydro power which can be used for local use. Small scale Micro hydropower stations combine the
advantages of hydropower with those of decentralised power generation, without the disadvantages of large
scale installations. Small scale hydropower has hardly any disadvantage: no costly distribution of energy,
no huge environmental costs as with large hydro, independent from imported fuels and no need for
expensive maintenance. Small scale hydropower can be used decentralised and be locally implemented andmanaged. Also, power generated with small hydro station can be used locally for agro-processing, local
lighting, water pumps, small businesses etc.
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2. HYDRAULIC TURBINES SELECTIONThe purpose of a hydraulic turbine is to transform the water potential energy to mechanical
rotational energy. It is appropriate to provide a few criteria to guide the choice of the right turbine for a
particular application. The potential energy in water is converted into mechanical energy in the turbine, by
one of two fundamental and basically different mechanisms:The water pressure can apply a force on the face of the runner blades, which decreases as it
proceeds through the turbine. Turbines that operate in this way are called reaction turbines. The turbine
casing, with the runner fully immersed in water, must be strong enough to withstand the operating pressure.
Francis and Kaplan turbines belong to this category.
The water pressure is converted into kinetic energy before entering the runner. The kinetic energy
is in the form of a high-speed jet that strikes the buckets, mounted on the periphery of the runner. Turbines
that operate in this way are called impulse turbines.
The Water enters the turbine, directed by one or more guide-vanes located upstream of the runner
and crosses it two times before leaving the turbine are called as cross flow turbine.
2.1 Impulse Turbines
Impulse turbines where one or more jets impinge on a wheel carrying on its periphery a large
number of buckets. Each jet issues water through a nozzle with a needle valve to control the flow. They are
generally used for high heads from 60 m to more than 1 000 m.
2.2 Reaction Turbines
Reaction turbines are mainly classified in to two. Those are Francis and Kaplan turbines.
2.2.1 Francis Turbines
Francis turbines are reaction turbines, with fixed runner blades and adjustable guide vanes, used
for medium heads. In this turbine the admission is always radial but the outlet is axial. Their usual field ofapplication is from 25 to 350 m head.
2.2.2 Kaplan Turbines
Kaplan and propeller turbines are axial-flow reaction turbines; generally used for low heads from 2
to 40 m. The Kaplan turbine has adjustable runner blades and may or may not have adjustable guide- vanes.
If both blades and guide-vanes are adjustable it is described as "double-regulated". If the guide-vanes are
fixed it is "single-regulated". Fixed runner blade Kaplan turbines are called propeller turbines. They are
used when both flow and head remain practically constant, which is a characteristic that makes themunusual in small hydropower schemes.
2.3 Cross-flow Turbines
Cross flow turbine is known as wide range of heads overlapping those of Kaplan, Francis and
Pelton. It can operate with heads between 5 and 200 m. It allows the water to pass through the runner and
crosses it two times before leaving the turbine. This simple design makes it cheap and easy to repair in case
of runner brakes due to the important mechanical stresses. The Cross-flow turbines have low efficiency
compared to other turbines and the important loss of head due to the clearance between the runner and the
downstream level should be taken into consideration when dealing with low and medium heads. Moreover,
high head cross-flow runners may have some troubles with reliability due to high mechanical stress.
It is an interesting alternative when one has enough water, defined power needs and low
investment possibilities, such as for rural electrification programs. In the above scenario, a cross flow micro
turbine is designed developed and tested for its performance.
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3. TURBINE DEVELOPMENT
In the hilly areas of Kerala state, especially where there are no electric grids, exist good potential
for development of micro hydropower for local use. Already some of the enterprising individuals are
running such micro hydro turbines for electricity generation in a limited way, by sacrificing the safety
standards. In most of the cases, the equipments are locally developed in a crude way. These equipments are
not dependable and frequently fail, require constant attention for repairs, which render them unviable.There is a necessity for introducing a cost effective, standard & reliable portable micro hydro
turbine generator set for the rural application, since no reliable set is available in local market, except for
some crude & locally manufactured sets or imported ones.
M/s Energy Management Centre, Trivandrum has collected general data regarding the requirement
of the range & rating of the micro turbines. The averaged head range proposed for micro turbine is from
20m to 50m and the output range is 10kw to 25kw. The type of turbine proposed was either cross flow or
Pelton, due to simplicity of construction & maintenance, which could be managed by the local technicians.
The final choice is for Cross flow at the first stage and Pelton subsequently.
Based on the above justification a 10kw cross flow micro turbine with an electric load controller is
developed. The turbine has a Stainless steel runner of 150mm diameter and a width of 130 mm with guide
vanes made of stainless steel. The turbine casting is made up of MS plate and shaft is made of carbon steel.Labyrinth seals and taper roller bearing are provided on the drive shaft. The prototype is design to develop
7.5kw on 35m head and a discharge of 160 m3/hr. The specifications of the turbine are
Head in m 20-40 Area of jet in sq. m 0.0155
Discharge 72-162 m3/hr Runner diameter in mm 150
Speed in rpm 800-1200 Runner width in mm 130
Number of blades 28
The fabrication, machining & assembly of the turbine were done by a small scale manufacturer in
Kerala. So that the local technicians can absorb the technology & duplicate the same depending on
requirement. Thus the benefits like gains of development of reliable and cost effective micro hydro turbineat the local level, easy availability & maintainability, improving the skills of local technicians and
generation of power at off grid area for isolated hill areas, etc are expected.
4. TURBINE TESTING
Whenever a turbine is designed and developed, is need to check for its performance in laboratory
condition or at site. Small hydro turbine can be tested in laboratory itself. Most of the bigger turbine it is not
possible to do testing in laboratory. In such case scale down model can be tested at laboratory and theoriginal testing can be done at site. The turbine has to be tested for finding out, its runaway speed and
efficiency.
4.1 Run away speed
When the plant is running at its rated condition, some time the load gets rejected from the grid. In
this condition the runner attained its maximum speed and it will be continued to run in the same speed without load for some time. Each runner profile is characterised by a maximum runaway speed. This is the
speed, which the unit can theoretically attain in case of load rejection when the hydraulic power is at its
maximum. Depending on the type of turbine, it can attain 2 or 3 times the nominal speed. During this
condition the turbine has to run without any mechanical problem. So it is necessary to measure the runaway
speed and check with the designers recommended runaway speed. For good design practice, the measured
runaway speed should be lesser than that of the maximum recommended runaway speed.
4.2 Turbine efficiency
It is really important to remember that the efficiency characterises not only the ability of a turbine
but also its hydrodynamic behavior. A very average efficiency means that the hydraulic design is not
optimum and that some important problems may occur (as for instance cavitation, vibration, etc.). That can
strongly reduce the yearly production and damage the turbine.
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The first is to carry out on site tests after putting the turbine into service. The second method
consists of performing laboratory tests on turbines geometrically similar to the industrial prototypes. In the
case of small hydropower plants, the size of the models being tested is often quite close to that of the actual
machines. The hydraulic behaviour of the turbine may be observed over the whole extent of its operating
range. It is thus possible to correct any possible shortcomings before the machine is actually built.
The efficiency guaranteed may be verified in accordance with the "International Code for the fieldacceptance tests of hydraulic turbines" (IEC 60041) or, if applied, in accordance with the "International
Code for model acceptance tests" (IEC 60193). It is defined as the ratio of power supplied by the turbine
(mechanical power transmitted by the turbine shaft) to the hydraulic power.
5. TEST PROCEDURE
For doing the performance evaluation of the selected cross flow turbine, a test setup is rigged up at
FCRI. The test setups consist of the equipments are as given below. The line sketch of the test set up is as
shown in figure 1.
The test setup consist of a dynamometer is coupled to the turbine, through the dynamic torque
transducer. The dynamometer was used for loading the turbine and torque transducer coupled in between
was used to indicate the torque applied by the dynamo meter. A non contact type tachometer is used formeasure the speed of the turbine. The turbine inlet was connected to the available test loop for simulating
the required flow, and the outflow from the turbine was allowed to flow the sump freely, without any draft
tube. Water from the sump was allowed to pass trough the turbine using a pump. A 6 Electromagnetic flow
meter is connected used for measuring the flow rate through the turbine. A precision pressure gauge is
connected for measuring the head of water just at the inlet of the turbine.
Sl. No EQUIPMENT SPECIFICATIONS PURPOSE
1 PumpFlow - upto 450 m^3/Hr
Head upto 100m
Water supply
to test rig.
2
Electromagnetic
Flow meter
Size - 6"
Flow Range 15 -600m^3/hrUncertainty - +/- 0.3151 m^3/hr
Flow Measurement
3 Precision Pressure GuageRange 0 100 m
Head measurementUncertainty - +/- 0.03% of reading
4 Torque TransducerRange 0 - 1000 N-m
Uncertainty - +/- 0.26 of FSTorque Measurement
5 TachometerRange 100-10000 RPM
Uncertainty - +/- 0.3 RPM
Turbine Shaft
Speed measurement
6 DynamometerRange - 11 kw
Intermittent Rating 150%Loading instrument
For the test, water was supplied from pump / constant head over head tank to the turbine at the
required heads of 50kpa to 500kpa pressures. Valve available at the upstream side and by pass line was
used to maintain the required head. The testing was done in different guide vane opening of 25%, 50%,
75% and 100%. Initially the turbine was allowed to run in its runaway speed for few minutes and the
runaway datas were collected. During the runaway testing the dynamometer was physically connected in
the test loop and is in switched of condition. During the switched of condition the dynamometer is freelyrotating along with the turbine. Then the turbine was loaded gradually by increasing the excitation voltage
of the dynamometer. At each step, the upstream head, discharge, speed and torque produced by the turbine
are noted down. From the test data the hydraulic power and mechanical power are calculated and the
efficiency of the turbine was derived.
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Plate A
6. TEST RESULTS
Measurements were done at 25%, 50%, 75% and 100% of guide vane opening. At each conditionhydraulic head, discharge, speed of the turbine, torque were measured.
At 25% guide vane opening data was collected for the head of 10 to 40 metre and speed range of
300 rpm to 2300 rpm. Maximum efficiency obtained was 24%.
At 50% guide vane opening data was collected for the head of 5 to 40 metre and speed range of
300 rpm to 2700 rpm. Maximum efficiency obtained was 30%.
At 75% guide vane opening data was collected for the head of 5 to 40 metre and speed range of
300 rpm to 3000 rpm. Maximum efficiency obtained was 44%.
At 100% guide vane opening data was collected for the head of 5 to 50 metre and speed range of
300 rpm to 3500 rpm. Maximum efficiency obtained was 55%.
From the measured parameters hydraulic power and mechanical power (Shaft power) are
calculated and the efficiency of the turbine derived as given below.
kwNT
powerShaftPowerMechanical60000
2)(
=
where
N speed of the turbine in rpm, T torque in N-m
kwxx
QhxPowerHydraulic
1000103600
81.9 =
where
- density in kg/m3 h head in kpa Q Discharge in m3/hr
For plotting the hill diagram, in z- axis the efficiency is plotted against the n11 in x axis, and Q11
in y-axis.
n11 & Q11 are calculated as below
headnet
diameterrunnerxspeedturbinen =11
headnetxdiameterrunner
edischQ
arg11=
Where
N - Speed in rpm, Q - Discharge in m3/hr
Runner diameter and head in metre,
The following plots were developed and reportedEfficiency speed Vs plot for different opening are shown in plot 1 to 4
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Plot 1: Speed Vs Efficiency at 25% opening Plot 2: Speed Vs Efficiency at 50% opening
Plot 3: Speed Vs Efficiency at 75% opening Plot 4: Speed Vs Efficiency at 100% opening
Hill diagrams are as shown in plot 5 to 8
Plot 5: Hill diagram at 25 % guide vane opening Plot 6: Hill diagram at 50 % guide vane opening
Plot 7: Hill diagram at 75 % guide vane opening Plot 8: Hill diagram at 100 % guide vane opening
7. CONCLUSION
The test results are encouraging and the turbine is producing maximum efficiency of 55% with a
head of 8 m to 10.5 m in 100% guide vane opening. Maximum efficiency was obtained with 100% guide
vane opening. Maximum efficiency for different guide vane opening is as in plot 9.
There is a further scope for improvement for improving the efficiency by modifying the guide
vane profiles. It is suggested to study the efficiency with different guide vane design for further
improvement.
Plot 1: Speed Vs Efficiency at 25% opening
Plot 2: Speed Vs Efficiency at 50% opening
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Plot 3: Speed Vs Efficiency at 75% opening
Plot 4: Speed Vs Efficiency at 100% opening
16
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Q11
0.455
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n11
20 30 40 50 60
Q11
0.54
0.56
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0.62
Plot 5: Hill diagram at 25 % guide vane opening Plot 6: Hill diagram at 50 % guide vane opening
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44
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n11
30 40 50 60 70
Q11
0.70
0.75
0.80
0.85
Plot 7: Hill diagram at 75 % guide vane opening Plot 8: Hill diagram at 100 % guide vane opening
8. REFERENCE
1. Report on Performance testing of Micro Hydro Turbine, A. Tamil Chandran, D.S. Anil Kumar,Jacob Chandapillai, Fluid Control Research Institute, Kanjikode, Kerala, India, April 2010.
2. Report on Performance testing of SHP stations A guide for developers, Manufactures andconsultants, Dr. Arun Kumar, Alternate Hydro Energy Centre, IIT- Roorkee, India, December
2009.
3. Report on Standards/Manuals/Guidelines for small hydro development, Alternate Hydro EnergyCentre, IIT- Roorkee, India Draft May 19, 2008.
4. Report on Turbine and test facility design, Alden/NREC fish friendly turbine, Thomas C, etallDepartment of Energy, United States, September 2000.
5. Micro Hydro turbine test facility at NERDC, T.A.Wickramasinghe, M.Narayana, InternationalConference on small hydropower- Hydro Srilanka, 22-24 October 2007.
6. Design optimization of cross-flow hydraulic turbine, M. Barglazan, Scientific bulletien of thePolitechnica, University Timisoaro, Volume 50(64), February 2, 2005.
7. Document on Development of a reliable micro hydro turbine for off grid operation M/s Energymanagement centre, Trivandrum, Kerala, India